Accounting machine



April 5, 1938; B. M. SHIPLEY ET AL ACCOUNTING MACHINE .Original Filed June 28, 1933 14 Sheets-Sheet 1 lnventois Berni: M. Shipley Pascal Sburlino and Everett H. Placke By Their Attorney April 5, 1938.

B. M. SHIPLEY ET AL ACCOUNTING MACHINE Original Filed June 28, 1933 14 Sheets-Sheet 2 I l Berni: M. $351, Pascal Sburlino and Everett H. Phcke Their Att omey April 5, 1938. B. M. SHIPLEY El AL ACCOUNTING MACHINE Original Filed June 28, 1933 l4 Sheets-Sheet 3 nton Shipley Pascal Sburlino and FIG. 5

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ACCOUNTING MACHINE Original Filed June 28, 1953 14 Sheets-Sheet 4 Inventor: Berni: M. Shipley Pascal Sburlino and B Everett H. P ache Their Attorney April 5, 1938. B. M. SHIPLEY ET AL ACCOUNTING MACHINE Original Filed June 28, 1933 14 Sheets-Sheet 5 Inventors Berni: M. Shipley Pascal Sburlino and Everett H. Placke [QM w Their Attorney April 5, 193-8.

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ACCOUNTING MACHINE Original Filed June 28, 1933 14 Sheets-Sheet 8 l t 4/0 Bernis Mf i i p igr Pascal Sburlino and Everett H. Placke Their Attorney April 5, 1938. B. M. SHIPLEY ET AL ACCOUNTING MACHINE Original Filed June 28, 1933 14 Sheets-Sheet 9 k5 manta-w FIG. 15

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Pascal Sburlino and Everett H. Placke Their Attorney April 5, 1938. B. M. SHIPLEY ET AL ACCOUNTING MACHINE Original Filed June 28,1935 H heets-Sheer. 11

Inventors Bernis M. Shipley Pascal Sburlino and Ev erett H. Placke y M M Their Attorney I 5, 1938. B. M. SHIPLEY ET AL ACCOUNTING MACHINE 14 Sheets-Sheet 12 Original Filed June 28, 1953 Inventors M. Shipley Pascal Sburlino and Everett H. Placke II I Berni:

a/vl/ as \L v Their Attorney April 5, 193-8. B. M. SHIPLEY ET AL ACCOUNTING MACHINE Original Filed June 28, 1933 14 Sheets-Sheet 13 MNMZL vm E m W rm v. 010 C e m mh m c 0 m m n DH A l mm =1 .1 v n mm b a aw T BPE A ril 5, 1938. B. M. SHIPLEY ET AL 2,113,412

I ACCOUNTING MACHINE Orig inal Filed June 28, 1935 14 Sheets-Sheet 14 MI! m7 l FIG. 30

Inventors Bernis M. Shipley Pascal Sburlino and Everett H. Placke V L Q: i

B M W Their Attornev Patented Apr. 5, 1938 PATENT OFFICE ACCOUNTING MACHINE Bernis M. Shipley, Pascal Sburlino, and Everett H. Placke, Dayton, Ohio, as'signors to The National Cash Register Company, Dayton, Ohio, a corporation of Maryland Original application June 28, 1933, Serial No. 677,-

980. Divided and this application July 27,

1936, Serial No. 92,705

18 Claims.

This invention relates to the type of cash registers known as accounting machines, and more particularly to the type of accounting machines used by banking and similar institutions. This case is a'division of applicants pending application Serial No. 677,980, filed June 28, 1933.

The primary. object of this invention is to provide a machine. adapted for use by banking and similar institutions.

, Other" objects of the present invention are to provide means for automatically line-spacing the traveling carriage when certain transactions are being computed, and to furnish novel means for controlling the linespacing means:

; With these and incidental objects in view, the invention consists of certain novel features of construction and combinations of parts, the essential elements of .which are set forth in appended claims and a preferred form or embodi ment of which is herenafter described with reference to the drawings which accompany and form part of this specification.

Of said drawings: 1

, Fig. 1 is a perspective of the complete machine.

5 Fig. 2 is a side elevation showing in detail the mechanism for releasing the machine by means of the total keys.

Fig. 3 is an elevation of the right side frame 1, showing the cycle control mechanism.

Fig. 4 is a detail view of the transfer mechanism for the auxiliary totalizer.

Fig. 5 is a cross section showing an amount bank and its associated diflerential mechanism.

' Fig. 6 is a sectional view of one of the transaction banks and its associated diflerential mechanism.

positioningthetotal plate. s

Fig. ,8 isa top plan view of the auxiliary to- 0 talizer audits differential mechanism. T 1

Fig. 9. is a side elevation illustrating apart of the interlocking mechanism between the transreleasingmechanisrm- 1 5 ,Fig. 10; isa detall view-of part'of-the machine releasingmechanlsm. 1

Fig. 11 is a sectional'view taken just to the right of an amount bankshowing the mechanism for, controlling the machine differentials in read and reset operations; w

Fig. 12 is a-sideelevation as observed from the right, showing the differential latch mechanism for the first transaction bank, :and' the mechanism for automatically breaking said latch mechanism.

I V ing, in a general way, the escapement mechanism. Fig. '7 isa cross section of the mechanism for action banks, the total keys, and the machine Fig. 13 is a detail view of the means for crippling part of the automatic latch-breaking mechanism when a key is depressed in the first transaction bank.

7 Fig. 14 is a side view depicting the manner in 5 which the automatic latch-breaking mechanism is controlled by the third transaction bank.

Fig. 15 is a diagrammatic view showing one amount bank, the three transaction banks, the total plate control keys, and the starting bar of the present machine. Fig. 16 is a diagrammatic view of the balance totalizer shifting cam and the auxiliary totalizer shifting cam. The cams are shown as they appear looking from the rear of the machine.

Fig. 17 is a facsimile of a fragment of a ledger or account card illustrating one form of transaction which is possible with the present machine.

Fig. 18 is a facsimile of a fragment of another ledger card.

Fig. 19 is a facsimile of a portion of a proof card.

Fig. 20 is a front elevation of a portion of the printing mechanism.

Fig. 21 is a front elevation of the mechanism which automatically controls the line-spacing of the sliding table.

Fig. 22 is a front elevation of the sliding table or traveling carriage with which the present machine is equipped.

Fig. 23 is a fragmentary end view as observed from the right, showing the method of mounting the sliding table to the machine.

Fig. 24 is a front view of the sliding table show- Fig. 25 is a front view showing in detail the escapement mechanism and part of its controlling mechanism.

Fig. 26 is a' detail view showing-the escapement releasing mechanism in ineffective position.

Fig. 27 isa detail view showing the escapement releasing mechanism in effective position.

Fig. 28 is an end view of the controlling mechanism for the sliding table escapement mecha- Fig. 29 is'a top view of part of the machine shown in Fig. 28.

Fig. 30 is a front view of a part of the mechanism shown in Fig. 28.

Fig. 31 is a top view of the operating yoke for the automatic line-spacingimchanism.

' Fig. 32 is a detail view of a part of the mechanism shown in Fig. 29.

Gunman. Dascm'rron The present invention is embodied in a machine of the type illustrated and described in Letters Patent of the United States Nos. 1,619,796, 1,747,397, and 1,761,542 issued respectively March 1," 1927, February 18, 1930, and June 3, 1930, to B. M. Shipley, and the copending application of M. M. Goldberg, filed August 27, 1931, Serial No.

Such mechanism of the present machine as is of standard construction, having been used in,

former machines, will be but briefly treated in both the general description and the detailed description to follow. However, reference may be had to the patents and' application referred to above and hereinafter for a more detailed description of the mechanism not thoroughly treated herein.

The machine of the present invention, while shown embracing a system for use by building and loan associations, is very flexible in its nature and with slight alterations may be adapted for use by various other business institutions where debits and credits are constantly being made against old balances, and new balances arrived at.

The machine embodying this invention is also provided with a novel mechanism for automatically line-spacing the record cards and has novel means for controlling that automatic mechanism. I

Dmmm DESGEIPTION Operating mechanism The machine of the present invention is preferably operated by means of the usual electric motor. Releasing the machine for operation automatically closes the electrical circuit and clutches the motor to the driving mechanism of the machine, from which it is automatically de- If desired, the machine may be hand-operatedby means of a crank (not shown) connected to the right end of a shaft I00 (Fig. 3). Secured to the left end of the shaft I00 is a pinion IOI (Fig. 3) which cooperates with a gear I02 pivoted on a stud I03 secured in a main-right frame I04. The gear I02 meshes with a gear I05 secured on the right-hand end of a main cam shaft I00, one end of which is -journaled in the right frame I04, the other end being journaled in a'left frame I01 (Fig. 6). The ledger frames 90 and 91 and the main frames I04 and I01, between which the bulk of the machine mechanism is supported, are mounted on a machine base 90 (Figs. 22 and 23). Depressing a starting bar I 08 releases the shaft I00 for rotation. The machine may then be operated by means of the hand crank and its associated mechanism.

Secured on the right end of the shaft I00 (Fig. 3) is a cam I09 which cooperates with a roller IIO pivotally mounted on. a lever III loose on a stud I I2 secured in the frame I04. A strong spring H3 is tensioned to urge the lever II I upward and, through the roller 0 and the cam I09,

assist the shaft I00 to its home position after the clutch mechanism has been disengaged near the end of an operation. Further explanation of this operating mechanism is deemed unnecessary, as reference may be had to the previously mentioned patents if a more detailed description is desired.

- Keyboard For illustrative purposes let us assume that the Calling attention to Figs. 1, 5, and 11, the machine as illustrated has nine amount banks II4, each containing nine amount keys H5. vEach amount bank carries a zero stop lever IIO, arranged to cooperate with the nose of a reset spider II'I loosely mounted on a hub I04 of a differential actuator I24, which in turn is pivoted on a hub II8,extending between two plates II9 (see also Fig. 8) supported by rods extending between the'main frames I04 and I0'I of the machine. 'I'he spider III has a notch I2I which embraces a stud I22 in the nose of a latch arm I23 pivoted ona differential actuator I 24. Shiftably mounted on the actuator I 24 by means of the arm I23 and another arm I25 is a latch I20. The arm I25 has a foot I21 arranged to cooperate with a notch in a driving segment I29 connected by a link I29 (Fig. 5) to a cam lever I30 loosely mounted on a stud carried by one of the plates H9. The cam lever I30 cooperates with companion cams I 3I and I32 secured on the shaft I00. In add operations, the shaft I06 makes one clockwise rotation, thereby rocking the lever I30 and the segments I29 first clockwise, as viewed in Fig. '5, then counter-clockwise to their normal positions. There is a differential actuator unit like that explained above for each amount bank. and each differential unit is supported between two of the plates H9. The entire assembly of differential units is held intact by means of a rod I33 extending through the hubs IIO.

- in a plate I30 supported by one of the plates II9. This breaks the latch in the zero position. If one of the keys H5 is depressed in an amount bank, the differential actuator I24 travels clockwise until the latch I20 engages the stem of the depressed key, causing the latch to break in the proper position, thereby differentially setting the actuator. After the foot I2! is forced out of the notch in the segment I28, the segment is free to continue its clockwise movement and an arcuate surface I 30 thereon engages the sole of the foot I21 to lock the actuator I 24 in its set position. Return movement home of the segment I28 releases the' latch I26 and returns the latch and actuator to normal position.

totalizer lines, three lines of interspersed. to-

talizers I38, I39, and I40 (Figs. and 11.), and an add-subtract or balance totalizer I. The totalizer lines I38 and I39 each have nine sets of totalizer wheels, which are actuated by the differential actuators I24. -The actuators I24 have three sets of teeth, one set for each of the totalizers I38 and I39 and a set for the addsubtract totalizer MI. The lines 838 and E39 are shiftable laterally in order that the desired set of totalizer wheels may be alined with the difierentialaotuators I24. A row of keys M2 (Figs. 1 and 15) controls the selection of the totalizers on line I38 and a row of keys 943 controls the selection of the totalizer on line 639. The mechanism which shifts the totalizers iaterally is old in the art and therefore will not be explained, but reference may be had to Patent No. 1,394,256 issued October 18, 1921, to F. L. Fuller for a detailed description of this mechanism.

The add-subtract or balance totalizer I has two sets of wheels, a positive set and a negative set. The keys I 42, in addition to selecting the totalizers on line I38, also select the positive side of the add-subtract totalizer for engagement with the difierential actuators, and the keys I43 likewise select the negative side of the balance totalizer for engagement with the differentials.

In'add operations, after the segments I28 have reached the end of their movement clockwise,

thereby setting the differential actuators H24 commensurate with the amount keys depressed, the selected set of totalizer wheels on one of the lines I38 or I39 (Fig. 5) and the proper side of the add-subtract totalizer are moved into engagement with the teeth on the differential actuators I24. The segments I28 then start their return movements, picking up all the differential actuators I24 and returning them to their home positions. This rotates the wheels of the selected totalizer commensurate with the amount set up on the keyboard. The totalizers are then disen= gaged from the differential actuators I24. The

differential actuators I24 have incorporated therein the usual transferring mechanisms for adding one to the next higher order wheel when the lower order wheel passes from 9 to zero. These transfer mechanisms are old and will not be further explained here, as reference may be had to the patents referred to hereinbefore for a complete description thereof.

Printer actuating mechanism Calling attention to Fig. 5, pivoted on each differential actuator I24 is a beam I44 bifurcated to embrace a stud I45 in a link I46. The link I46 exends between a toothed segment I41 loosely mounted on a shaft I48 pivoted between the main frames of the'machine and an arm of a gear segment I49 loose on a shaft I150. The segment I49 cooperates with a gear I6I secured on a shaft I62, which cooperates with the well known printer rack mechanism to position the printer wheels in a manner now to be described.

The Y-shaped cam arm I30 (Fig. 5) has a roller I63 which cooperates with an arcuate surface on the beam I44 to force the beam against the hub I64 on the actuator I24 after said segment has been differentially positioned, as pre-= is rotatably supported by the stud I03, but durviously described. This, through the link I46, positions the segments I41 and I49 commensurate with the position of the differential actuator I24, thereby properly positioning the associated printing wheel. After the segment I41 has been positioned, an aliner I65 fast on a shaft I66 (Fig. 5)

race B82 in the gear B62.

engages one of the tooth spaces therein to assist Calling attention to Fig. 3, in add operations the shaft I 06 makes one revolution to operate the differential mechanism through one cycle of movement. In read and reset operations it is necessary that the difierential mechanism operate through two cycles of movement. Therefore, it is necessary to rotate the shaft I06 two complete revolutions in such operations. This is accomplished by means of cyclecontrol mechanism which controls the disengaging of the motors clutch in a manner now to be described.

Journaled between the main frames I04 and I01 is a key lock shaft I61 having secured on its right end an arm I68 carrying a stud I66 embraced by a slot in the upper end of a link I10 bifurcated on its lower end to receive a stud in a pitman i'li slotted to embrace the stud I03. The lower end of the pitman I1I is pivotally connected to an arm i112 journaied on a stud I13 carried by the frame tilt. The arm I12 has an extension I16 connected by a link 915 to an arm I16 secured on a zero latch throwout shaft I11 (see also Fig. 9) extending through the machine and journaled in the main frames GM and I01.

The link tilt has a stepped opening I18 which cooperates with a stud 819 in a cam arm I pivoted on the stud its (Fig. 3). The arm 880 carries a roller E86 which cooperates with a cam The race N32 has diametrically opposed cam sections which cooperate with the roller Wit near the end of each cycle of movement to rock the arm I80 first clockwise, then back to normal position. Retained in slot in the link 318 by means of a projection is a spring Q83 operatively connected to the arm 568, which spring is compressed to urge the shaft 861 clockwise.

In Fig. 3 the cycle control mechanism is shown in its normal or adding position. Releasing the machine for an add operation by depressing the motor bar I08 frees the shaft E61 to the action of the spring I83, which forces the shaft clockwise until the arm I68 strikes a stop stud H86 secured in the frame I04. This movement of the shaft I61 engages the motor clutch and locks the amount' keys in the well known manner.

As previously explained, the shaft it makes one revolution clockwise in add operations and the gear I02 makes one-half revolution counterclockwise. Just as the gear I02 is completing its movement, the arm I80 is rocked clockwise and back, as previously explained, and the stud I18 at this time engages the top step in the opening I18, the link I10 receives its maximum downward movement. This declutches the motor from the driving mechanism and releases the depressed keys in the usual manner.

In totai taking operations, both read and reset, it is necessary that the shaft I06 make two clockwise revolutions and the gear I02 one counter-' clockwise revolution. This is accomplished in the following manner. The pitm'an I1l carries a roll I85 normally retained in a notch in a cam I86 but adapted to cooperate at certain times with a race I81 in said cam I86. The cam :66

ing add operations is retained immovable by means of the roller I85 engaging the notch therein.

Loosely mounted on the shaft I61 (Figs. 3 and 9) is an arm I88, connected by a link I89 to the arm I12. The arm l99 has pivoted thereto a link I90 having a'stud I9I which engages a slot in a plate I92 pivoted on a stud I99 secured in the frame I09. The link I90 has fast therein another stud I arranged to cooperate with a projection I6I on the arm I69. The plate I92 has another slot embracing a stud I99 in an arm I95 of a yoke I96 loose on a shaft I91 (see also Fig. 2). The yoke I96 is bifurcated to receive a stud I99 in a link I99 connecting the upper ends of key plates 200 and 20I mounted for slight radial movement on studs 209 and 209 carried by a total key frame 202 (Fig. 7). r

A link 206 connects the lower ends of the plates 200 and 20I in exactly the same manner as the link I99 connects the upper ends. Each plate 200 and 20I has three sets of slots 206, 201, and 209 (Figs. 2 and 9) arranged to cooperate with studs 209 carried by a new balance key 2I0, total reset keys 2I I, and total read keys 2| 2 (see also Fig. 7). These slots are so arranged that each plate 200 and 20I receives a varying degree of movement for each corresponding read and reset key depressed. However, the combined movement of both plates is always the same, and consequently the stud I99 moves the same distance regardless of which total key is depressed.

The arm I99 (Fig. 3) and connecting mechanism are retained in normal inefiective positions by. a spring 2I9 tensioned between an extension of the arm I69 and one end of a lever 2| 9 pivoted on a stud 2I6 secured in an auxiliary frame 2I6 supported by the frame I09. The lever 2I9 is connected by a link 2I1to the arm- I99. Thus the spring 2I9 retains the arm I99 in normal position against the stop stud I99 and at times when said arm and the shaft I61 are rotated in unison, their action is compensated for by the link 2I1 so that no additional burden is placed upon the shaft I 61.

Depression of any of the keys 2I0, 2I I, or 2I2 (Fig. 7) moves the plates 200 and 20I (Figs. 2 and 9) downwardly, thereby rocking the yoke I96 counter-clockwise. This movement of the yoke I96, through the stud I 99, rocks the plate I92 counter-clockwise and the link I90 clockwise to move the stud I60in the path of the projection I6I on the arm I69. The yoke I96 (Figs. 2 and 9) has an arm 2I9 with a surface which cooperates with a stud 2I9 in an arm of a yoke 220 loose .on the shaft I61. The yoke 220 has an arm 22I (Fig. 10) bifurcated to receive a stud 222 in a release pawl 229 on the shaft I91 and adapted to cooperate with a release arm 229 secured on the shaft I61. A spring 226 is tensioned to hold the pawl 229 in the path of the arm 229.

Rocking the yoke I96 counter-clockwise by depressing any of the total keys, as explained above, causes the arm 2| 9, through the stud 2I9, to rock the yoke 220 clockwise. This in turn rocks the pawl 223 counter-clockwise to release the key lock shaft I61 to the action of the spring I99(Fig. 3) as explained above. The clockwise releasing movement of the shaft I61 through the arm I69 rocks the arm I99 in unison therewith. Thisj through the link I 99 and arm- I12, gives the shaft I11 a slight movement clockwise and moves the pitman I1I forwardly, causing the roller I96 to move into the raceway I91 in the cam I96 and couple'said cam to the gear I02 in the well known manner. This movement of the pitman I 1| also rocks the link I10 clockwise.

During rotation of the gear I02 and consequent rotation of the cam I96 in unison therewith, the raceway in said cam I96 cooperating with the izer.

,92I carried by the plate 9".

added movement, thereby placing the link I19 in a position where the stud I19 is free to move idly in the long part of the opening I19 when the 'cam arm I90 is rocked by the raceway I92. This prevents restoring the key lock shaft I61 during the first cycle of operation, thereby allowing the machine to operate through another cycle, near the end of which the cam I96 moves the pitman HI and link I10 to a position where the stud I19 will again engage the horizontal section of the opening I19 when the arm I99 is moved downwardly, which restores the key lock shaft I61 to normal position and releases the The add-subtract totalizer embodied in this machine is similar to that used in previous machines of this type. There is an adding wheel and a subtracting wheel for each denominational unit (Figs. 4 and 5), corresponding wheels of each denominational unit being geared together in the well known manner so that they revolve in opposite directions. These sets of add-subtract totalizer wheels are loosely mounted on the shaft I9I, which is in turn secured in a slidable frame (not shown) controlled for engagement with the differential actuators I29 in a manner to be later described in connection with the auxiliary total- The add-subtract totalizer 'is selected for addition or subtraction by shifting the shaft I so that the desired set of wheels are alined with the differential actuators I 29. This is accomplished by means of the first transaction bank latch plate 9I0 (Figs. 6, 12, and 14) which operates similarly to the reset spider II1 (Fig. 11) of the amount bank and through an arm 9I I controls the breaking of a first transaction latch 9 I2. The latch 9I2 is pivoted to an arm 9 by means of the arm 9 and a link 9 and has a foot which cooperates with a notch in a driving segment 9I6 pivoted on a hub 9I9 extending between plates 9" and 9 supported by the rods I20. Substantially all the mechanism of the first transaction bank is mounted between the plates 9" and H9 (Fig. 8). A link 9I9.connects the segment 6 to a cam arm 920 pivoted on a stud The lever 920 carries rollers 922 and 929 which cooperate with companion cams 929 and 926 secured to the shaft I06. The arm 9 isturnably mounted on the hub 916 and has pivoted thereto a beam 929 bifurcated to embrace a stud 921 in a link 929 extending between an alining segment 929 and an arm 930 of a printer drive segment I lournaled on the shaft I90. The segment 9291s secured to a yoke 992 fast to the shaft I99. The segment 929 has a plurality of teeth 999 which cooperate with the alining bar I66 secured to the shaft I66.

Again directing attention to Fig. 6, the beam 929 has an arcuate surface 996 which cooperates with a roller 996 carried by the arm 920. A first transaction bank 991 has therein keys 999, 999.

and 990. Depressing any of these keys places the lower end of the stem thereof inthe path of the arm 9 to break the latch 9| 2 and differentially position the latch plate H0 and arm 9 commensurate with the depressed key. There is also automatic means, to be explained later, for break in this bank are depressed and the automatic latch-breaking mechanism is ineffective, the latch plate 8 and arm 4I3 travel to the ninth position, where the latch is automatically broken by means of a stud carried by the first trans action bank frame engaging the end of the latch plate 4I8. After the plate 4I3 has been differentially positioned by one of the means previously described, 'the roller 436 engages the arcuate surface 435 of the beam 426, forcing said beamagainst a hub I to differentially position the segments 429 and 43I and the shaft I48 commensurate with the position of the arm M3. The segment 43I is geared to a pinion 45!] fast on a shaft 45I journaled between a pinion frame 452 and a front printer frame 453 (see also Fig. 28). The shaft 45I drives a rack (not shown) which positions the printing wheels for the first transaction bank 431 and also controls the automatic line-spacing -mechanism to be later described.

Secured to the left end of the shaft I48, and consequently rotated in unison therewith (Figs. 8 and 16), is an auxiliary totalizer shifting cam 442having an arm 443 connected by a link 444 to an add-subtract totalizer shifting cam 445, pivoted on a stud not shown, carried by the left frame I81. The stud which supports the shifting cam 445 is on the same center as the differential actuators I24. The cam 445 moves in synchronous order with the cam 442, due to its connection thereto, and as the cam 442 is positioned by the latch mechanism of the first transaction bank, the cam'445 is likewise positioned according to the location of said first transaction bank latch mechanism. By referring to Fig. 16 it will be seen that both the cams 442 and 445 have'ten positions. The four upper positions of the cam 445 shift the add-subtract totalizer frame to the right (as viewed in Fig. 8, or to the left as viewed in Fig. 16) thereby alining the plus set of totalizer wheels with the actuators I24. The four lower positions of the cam 445 shift the add-subtract totalizer frame to the left (Fig. 8) to aline the negative set of totalizer wheels with the actuators, The cam 445 has two neutral positions which retain both the positive and negative sets of totalizer wheels out of engagement with the differential actuators I24.

From the foregoing description it will be seen that when the latch 2 (Fig. 6) is broken inthe zero, first, second, or third position, the negative side of the add-subtract totalizer will be selected for engagement with the actuators, and when the latch H2, is broken in the sixth, seventh, eighth, or ninth position, the positive side of the addsubtract totalizer will be selected for engagement with the diflerential actuators I24, andwhen the latch H2 is broken in the fourthor fifth position, neither set of totalizerwheels will be selected for engagement with the diflerentials.

As previously stated, the mechanism which shifts the totalizer lines I38, I39, and I4] laterally has been neither illustrated nor described} in detail herein, as reference maybe had to the Fuller Patent No. 1,394,256 for a complete description of this mechanism.

The means'for engaging the add-subtract totalizer with the difierential actuator I24 is so closely allied to the engaging mechanism for the auxiliary totalizer that it is deemed advisable to describethese mechanisms together in the following description of the auxiliary totalizer mechanism. The same is true of the reset shaft 316 (Fig. 11) for the add-subtract totalizer.

Auxiliary totalizer mechanism Directing attention to Figs. 4, 5, and 8, the auxiliary totalizer mechanism is supported be tween the plate 2 I6 and a-left auxiliary plate "I secured to the left frame I01. The plate 2I6 supports an intermediate plate 412 which also assists in supporting the auxiliary totalizer mechanism. The auxiliary totalizer I40 is similar in construction to the front and rear totalizers I38 and I39 and has six sets of interspersed totalizer wheels rotatably mounted on a tube 413 secured in arms 414 and 415, loose on an engaging shaft 416, the ends of which are supported in slots (not shown) in plates 419 and 480 of the usual type secured respectively to the plates 2I6 and 41I. Secured on opposite ends of the shaft 416 are arms 48I and 482 carrying anti-friction rollers which extend within duplicate cam slots of the plates 419 and 488. The arm 415 (Fig. 8) carries a pin 486 upon which is journaled a flanged roller 481, the upper end of which is embraced by a lateral slot 488 in a bracket 489 secured to the plate 41I. The lower end of the roller 481 extends within a slot 498 in the auxiliary shifting cam 442 (see also Fig. 16). Movement of the cam 442 shifts the auxiliary totalizer laterally to aline the selected set of totalizer wheels with a plurality of difierential actuator segments 492. The auxiliary totalizer line is guided in its lateral movement by the slot 488 in the bracket 489 and by the shaft 416.

The present machine is equipped with nine amount banks and one overflow bank. Consequently there are ten of the differential actuators I24 (Fig. 5) and ten corresponding auxiliary actuator segments 492. Each of the segments 492 is rotatably supported by the shaft I48 in vertical alinement with its corresponding actuator I24. Corresponding actuators I24 and segments 492 are connected for concert movement by a link 493. Consequently the differential movement of the actuator I24, which is controlled in adding operations by the amount keys I I3, is transmitted to the auxiliary actuator segments 492.

Automatic latch-breaking mechanism The latch of the first transaction bank, in addition to being broken by means of the keys 438,

439, and 440 (Figs. 6 and 15), is also broken automatically in various positions. Itwill be remembered that the first transaction bank latch controls the selection of the plus or minus side of the add-subtract totalizer and also controls the selection of the different totalizers on the auxiliarytotalizer line in all operations including add, read, and reset.

The first transaction bank (row 1') latch has ten positions, zero to 9 inclusive. Movement of this latch controls the positioning of the cams 442 and 445 (Fig. 16) which in turn respectively control the selection of different sets of totalizer wheels on the auxiliary totalizer line and the plus or minus side of the add-subtract or balance totalizer. Positions zero to 3- inclusive of the cam 445 select the minus side of the add-subtract totalizer and positions '6 to 9 inclusive select the plus side of the add-subtract totalizer.

It requires two positions of the cam 445, in

this instance positions 4 and 5, for the shifting of the add-subtract totalizer in order to aline the positive or negative side thereof with the actuators. There are keys in both these positions, but the account number key, fourth position, is merely a printing key, that is, it is used to release the keyv lock line when it is desired to print an account number on the ledger card or passbook.

The proof key, fifth position, has a short stem and consequently does not stop the latch which is, in this position, controlled automatically. The automatic latch-breaking mechanism will now be described in detail.

Mounted for slight rocking movement on studs 208 and 204, carried by the total key frame 202 (Figs. '7 and 14) ,is a plate 808 having slots 809 and'8I0, which cooperate with studs 209 in the new balance or first reset key 2I0 and the first read'key 2I2 (see also Fig. 15). The plate 808 is bifurcated to embrace a stud 8 in an arm 8I2 loosely mounted on the upper reset shaft I91. The arm 8| 2 has a hook 8l8 which cooperates with a square stud 8I4 in one arm of a yoke 8I5 loosely mounted on a shaft 8I6, opposite ends of which are journaled in the plate 464- (Figs. 6

and 8) and a plate 8| 1., carried by the first transaction bank hanger H8. The plate 808 (Fig. 14) has symmetrical slots 8I8, which cooperate withv the studs 209 carried by the second and third reset and read keys 2 and 2I2 respectively. The

arm 8I2 carries a stud 8 I9 which cooperates with an arm 820 secured on a shaft 82I journaled in the plates 464 and 8I1.' Secured on the shaft 82I is another arm 822 having a stud828 which cooperates with an arm 824 loose onthe shaft The arm 824 carries a stud 825, arranged I91. to engage a key lock line latch 826 loose on the shaft I91.

When the machine is in home position, a spring (not shown) retains the latch .826 in engagement with an arm 821 fast on the key lock shaft I61.

Depressing any one of the keys 2I0, 2I I, and 2I2 rocks the plate 808 and the arm 8I2 counterclockwise. This in turn rocks the shaft 82I and arm 822 clockwise, which, through the arm 824, moves the latch 826 counter-clockwise to release the key lock line for its clockwise releasing movement, as previously described herein. Restoration counter-clockwise of the key lock line I61 near the end ofmachine operation allows the latch826 to reengage the arm 821 to lock the shaft I61 against releasing.

Depressing a key in either the first, second, or third transaction bank likewise rocks the latch 826 counter-clockwise, so that the shaft I61 will be free to make its releasing movement clockwise when the starting bar I08 is depressed. From the foregoing it will .be seen that depressing one of the keys 2I0, 21 I, or 2| 2 releases the machine for operation, but before the machine can be released by depressing the starting bar I08 it is necessary that a key be depressed in either the first, second, or third transaction bank.

Depression of either the new balance key 2I0 (Fig. 15) or the first read key 2I2, due to the angle of the slots 808 and 810 (Fig. 14), rocks the plate 808 and the arm 8| 2 full distance counter-clockwise. This moves the hook 8I8 out of the path of the stud 8, thereby surrendering the yoke 8I5 to the control of other means to be later described. Depression of any other key in the total bank rocks the plate 808 and the arm 8 I 2 only partial distance counter-clockwise, which is not sumcient to move the hook 8I8 out of the path of stud 8; therefore the yoke 8I5 is retained in ineffective position.

The arm 8I2 (Figs. 12 and 14) has a stud 828 which cooperates with a forked projection of a yoke 829 loose on the shaft 82I. An arm of the yoke 829 has steps 880, 88I, and 882 which cooperate with a stud 888 carried by an upward extension of a latch stop arm 884 pivoted on a stud 885 carried by the hanger plate 4I8 for the first transaction bank (see Fig. 6). The arm 884 has a projection 886, which coacts with a projection 881 on the first transaction bank latch plate 4I0.

to aline the step 88I thereon with the stud 888 in the arm 884. The purpose of the above movements of the yoke 828 will be revealed later.

Calling attention to Fig. 12, fast on the key lock shaft I61 is an arm 888 connected by a link 840 to a plate 8, rotatably mounted on the shaft "I. A foot 842 of 'the link 840 cooperates with the stud 888 to restore the arm 884 to normal position near the end of each machine operation in a manner to be described later. The plate 8 has an arcuate surface 848 which coacts with a stud 844 carried by one arm of a yoke 845 turnably mounted on the shaft 8I6. Initial releasing movement clockwise of the shaft I61 (Fig. 12) rocks the foot 842 of the link 840 away from the stud 888 in the arm 884, and rocks the plate 8 counter-clockwise. This movement of the plate 8 disengages the arcuate surface 848 thereon from the stud 844 in the yoke 845 for a purpose to be later described. The yoke 845 has an extension 846 (Fig. 12) which cooperates with a stud 841 in an arm 848 of the yoke 815. Another extension 849 (Fig. 14) of the yoke 845 coacts with a stud 850 in an arm 85I secured to the shaft 8I6. Secured on the shaft 8I6 is a latch stop pawl 852 (Fig. 14), the end of which is adapted to cooperate with a projection 858 on the plate 4I0. Also fast on the shaft 8I6 is an arm 854 carrying a stud 855 which coacts with a projection 856 (Fig. 14) of a plate 851 mounted for slight rocking movement on the center I88. The plate 851' has angular camming surfaces 858 arranged to be engaged by studs 859 carried by the keys I48 (Fig. 15) of the third transaction bank. The stud 841 in the arm 848 of the yoke 8I5 (Fig. 12) is arranged to be engaged by a radial projection 860 on a plate 86I turnably mounted on the center I88 and having angular camming surfaces 862 which cooperate with studs 868 carried by the keys 438, 489, and 440 of the first .transaction bank. The plate 86I (Figs. 12 and 13) carries a stud 864 embraced by the bifurcated end of an arm 865 rotatably supported on the shaft 82I, and having, an extension 866 which cooperates with the stud 888 carried by the stop arm 884 in a manner and for a purpose to be later described. The plates-851 and 86I (Figs. 12 and. 14) are returned .to and retained in normal positions as here shown against stop studs 861 and 868 secured in the hanger plates 4I1 by springs 869 and 810 respectively.

Loose on the shaft M6 is a pawl 81I (Fig. 6)

which cooperates with steps 812 and 818 of a plate 805 secured to the first transaction bank latch plate 4I0.

The pawl 81I has an extension 814 which cooperates with a disabling arm 815 loose on the overdraft shaft 468. The arm 815 has a stud 816 embraced by the bifurcated end of an arm 811 loose on the shaft MI. The extension 814 of the pawl 81I is maintained in engagement with 

